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US8709359B2 - Sample holder and method for treating sample material - Google Patents

Sample holder and method for treating sample material
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US8709359B2
US8709359B2US12/984,919US98491911AUS8709359B2US 8709359 B2US8709359 B2US 8709359B2US 98491911 AUS98491911 AUS 98491911AUS 8709359 B2US8709359 B2US 8709359B2
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holder
sample
vessel
support structure
sample material
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US20120167786A1 (en
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James A. Laugharn, Jr.
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Covaris LLC
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Covaris LLC
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Priority to PCT/US2012/020149prioritypatent/WO2012094374A2/en
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Assigned to COVARIS, LLCreassignmentCOVARIS, LLCCHANGE OF NAME (SEE DOCUMENT FOR DETAILS).Assignors: COVARIS, INC.
Assigned to ARES CAPITAL CORPORATION, AS ADMINISTRATIVE AGENTreassignmentARES CAPITAL CORPORATION, AS ADMINISTRATIVE AGENTSECURITY INTEREST (SEE DOCUMENT FOR DETAILS).Assignors: COVARIS, LLC
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Assigned to BLUE OWL CAPITAL CORPORATIONreassignmentBLUE OWL CAPITAL CORPORATIONSECURITY INTEREST (SEE DOCUMENT FOR DETAILS).Assignors: COVARIS, LLC
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Abstract

Method and apparatus for holding and/or treating a sample material. A sample material may be positioned in a vessel between top and bottom flexible films where the flexible films are connected together by a substantially rigid support structure that surrounds the sample material. A crushing force may be applied to the sample material via the top and bottom flexible films, e.g., to pulverize the sample at cryogenic temperatures. A sample holder may have two vessels, one arranged for applying a crushing force to a first sample and another for holding a sample for other processing, such as a histology analysis.

Description

BACKGROUND
A first step in sample analysis typically involves collecting the sample. For example, a first step in a biological analysis such as RNA gene expression profiling or protein biomarker profiling is to collect a particular sample so that its biochemical constituents can be analyzed. However, prior to such analysis, a solid sample specimen, typically, is prepared by deconstructing it into a plurality of smaller fragments of the specimen to enable more accurate analysis.
A challenge of sample preparation is that the types of samples are diverse. For example, samples may be biological, non-biological or a combination thereof. They may be from animals or plants. Samples may include, without limitation, cells, tissues, organelles, bones, seeds, chemical compounds, minerals, metals, or any other material for which analysis is desired.
Sample preparation is particularly challenging for solid biological samples, such as tissue samples. Physical and/or chemical approaches are often employed to disrupt and homogenize the solid sample for biochemical extraction. While appearing deceptively simple, transitioning a sample of biologically active tissue, for example, on the order of 1 gram, to a plurality of biomolecules that are stabilized and isolated in an appropriate analytical solution is exceedingly complex, very difficult to control, and prone to introduction of errors and/or sample constituent degradation.
Another challenge associated with sample preparation relates to the lability of the target molecules. For some applications, an overriding criterion is to retain the native biochemical environment prior to sample collection and throughout the extraction process, without perturbing the biochemical constituents to be analyzed. For example, RNases are extremely robust and may significantly degrade the mRNA profile of a tissue sample if the RNases are not immediately stabilized (typically thermal or chemical inactivation) at the time of tissue collection and during sample processing or homogenization. Often, to minimize perturbation of the biochemical profile of the sample, the tissue is flash-frozen (e.g., via direct immersion of the sample following procurement in liquid nitrogen) and stored at cryogenic temperatures (e.g., −80 degrees C. or lower), which inhibits degradative processes.
SUMMARY OF INVENTION
Aspects of the invention address at least some of these challenges by providing, in various embodiments, systems, methods and devices for collecting, stabilizing, fragmenting and/or analyzing samples. As described above, analysis of biological and non-biological sample specimens often begins with collection of a sample of relatively large size. Before the constituents of such a sample can be effectively analyzed, the sample, preferably, is fragmented into a plurality of smaller specimens. Such smaller specimens can then be stored, analyzed, or further processed. In one embodiment, a sample holder includes two vessels arranged so that one portion of a sample may be placed into a first vessel and another portion of the same sample may be placed into a second vessel. The first vessel may be arranged to allow the sample to be frozen (e.g., by exposure to liquid nitrogen or other suitable cryogen) and then fragmented, broken, or otherwise crushed without removing the sample from the first vessel. The second vessel may be arranged to store the sample under conditions suitable for later histologic or other analysis of the sample. Thus, the two sample portions may be kept together on a common support, e.g., so that if analysis results of one sample portion require the use of the other sample portion for other tests or confirmation of the first analysis, one can be assured that the sample portions originated from the same subject and have been stored under the same or similar conditions.
A sample may be any material. Exemplary samples include, but are not limited to, bones, teeth, seeds, plants, pathological or non-pathological animal tissue (e.g., muscle, liver, kidney, lung, brain, pancreas, prostate, ovary, breast, etc.), tumor tissue, rocks, mineral samples, tree bark, and/or food products. Exemplary constituents include, but are not limited to, nucleic acids, amino acids, polypeptides, bacteria, viruses, fungi, spores, small organic molecules, small inorganic molecules, metals, minerals, ores, and the like. The sample may be relatively soft, such as a tissue sample, may be relatively hard, such as a bone or mineral sample, and may include sharp knife-like edges and/or sharp needle-like points. By way of a more particular example of the medical application of the invention, it may be used to process pathological and/or non-pathological tissue samples harvested from a patient. Such samples include, but are not limited to, putative tumor samples taking during a biopsy.
In one aspect of the invention, a sample holder includes a support structure defining first and second vessels, with each of the vessels including a top opening, e.g., into which a sample portion may be placed. First and second covers may be each removably engageable with the support structure so as the close the top opening of the first and second vessels, respectively. For example, the covers may be in the form of a cap that is arranged to seal a corresponding vessel closed and be openable to allow retrieval of all or part of a sample portion from the vessel. The first vessel may be arranged to contain a first sample material and transmit a crushing force exerted on the first vessel to the first sample material so as to crush the first sample material. For example, the vessel may be placed in a device arranged to apply a crushing impact force to the first vessel and first sample material, e.g., as described in U.S. Patent Publication US 2005/0132775 which is hereby incorporated by reference in its entirety. The second vessel may be arranged to contain a second sample material suitable for a desired analysis process, such as a histology analysis.
A sample holder arranged like that described above may provide advantages such as allowing a sample harvester (such as a doctor taking a biopsy sample) to place one portion of a sample in the first vessel and another portion of the same sample in a second vessel. The two sample portions may be stored together, experiencing the same, or similar, conditions. In addition, by harvesting and placing the sample in the vessels at the same time, there may be confidence that the samples originated from the same source, were taken using the same or similar techniques, and so on. Accordingly, if analysis of a first sample portion (e.g., resulting from the first sample material in the first vessel being crushed and subsequently subjected to a molecular analysis to identify whether a particular compound is present) suggests that further or different analysis is required, the second sample portion in uncrushed or other form may be used (e.g., as part of a histology analysis). In some embodiments, the second vessel may be separable from the first vessel, e.g., the second vessel may be used as a histology cassette.
In another illustrative embodiment, a sample holder may include a support structure defining a substantially rigid sidewall of a vessel, a bottom opening of the vessel, and a top opening of the vessel. A first layer of flexible film may be attached to the support structure so that the first layer of film covers the bottom opening, and a second layer of flexible film may be attached to the support structure so that the second layer covers the top opening. The first and second layers may be separated from each other by at least a part of the sidewall and be arranged to transmit a crushing force exerted on the first and second layers to crush a sample material contained in the vessel, e.g., between the first and second layers and within the sidewall. By having the flexible films separated from each other by a substantially rigid sidewall, the sample material in the vessel may be crushed, yet the vessel may retain at least some of its initial shape and/or size. This is in contrast to bag-type sample holders that are commonly used for sample crushing. While these bag-type sample holders are very effective, retrieval of a crushed sample may require that the bag be manipulated to separate the bag layers from each other and/or move the sample to a desired location in the bag. Sample holders in accordance with some embodiments may allow for crushing of the sample while maintaining the sample in a relatively defined space that can be easily accessed.
The sample holder may be arranged for use with a variety of analysis tools, such as microscopes and other imaging devices, impact devices, microtome devices, acoustic treatment devices, and so on. For example, the sample holder support structure may define a generally planar body in which the sidewall is defined and/or from which the sidewall extends, e.g., the support structure may define a shape similar or identical to a microscope slide and the sidewall may extend upwardly from the planar body and/or have a cylindrical shape. Films on top and bottom sides of the planar body may close top and bottom openings defined by the support structure, and thereby define a vessel in which a sample material is held. In one embodiment, a sample contained in the vessel may be held by the vessel for viewing in a microscope or other imaging system either before or after the sample is crushed while in the vessel.
In some embodiments, the first and/or second layers of flexible film may have a convex shape such that a portion of the first and/or second layer extends into the vessel, or the first and/or second layer may have a concave shape such that a portion of the first and/or second layer extends away from the vessel. The concave and/or convex shapes may provide certain features, such as providing a well or other area in which a sample is held, may help hold a sample in place in the vessel (e.g., by squeezing the sample in place between the two layers), may help direct a sample or portions of the sample to specific areas in the vessel, and so on. The first and/or second layers may be formed of a polyimide, a polysulfone, a fluorinated polymer, a liquid crystal polymer or other suitable material. For example, the first and second layers may be arranged to transmit the crushing force to the sample material while at temperatures less than about −40 degrees C., e.g., after the vessel and sample are immersed in liquid nitrogen or are otherwise exposed to cryogenic conditions. The first and second layers may transmit the crushing force to the sample material at such low temperatures without cracking, tearing, or ripping when exposed to the crushing force. This can be a useful property, particularly if the sample is relatively hard, e.g., includes a seed, bone, rock, stone, sand, glass, metal, tree bark, and fragments and combinations thereof, and/or when the crushing force transmits significant energy to the sample, e.g., of at least up to about 10 Joules or more. The first and second layers may have any suitable thickness, e.g., of between about 0.5 mil and 5 mil.
In one illustrative embodiment, a sample holder may include a support structure that defines a sidewall of a vessel having a bottom opening and a top opening. A first layer of flexible film may be attached to the support structure to cover the bottom opening, and a cap may be removably engageable with the support structure so as the close the top opening of the vessel. The cap may include a cap opening and a second layer of flexible film may cover the cap opening. The first and second layers of film may be arranged to transmit a crushing force exerted on the first and second layers to crush a sample material contained in the vessel. The vessel may be sealed in a substantially air tight fashion when the cap is engaged with the support structure, e.g., to isolate a sample in the vessel from an external environment. The top and bottom openings may have any suitable size and/or shape, such as a circular opening with a diameter of about 20 mm. The first and/or second layers may be substantially flat or have a concave or convex shape, e.g., a convex portion that extends into the vessel and has an outer diameter of about 5 mm and a height of about 2 mm.
In another aspect of the invention, a method of treating a sample material includes providing a sample material between top and bottom flexible films where the flexible films are connected together by a substantially rigid structure that surrounds the sample material, and applying a crushing force to the sample material via the top and bottom flexible films. The first and second films and the structure may be arranged like that described above, e.g., in an arrangement that defines a cylindrically-shaped space in which the sample is held and a crushing force is exerted from opposite ends of the cylindrically-shaped space.
In another aspect of the invention, a method for treating a sample material includes providing first and second portions of a sample material. The first and second portions may be obtained from a single piece of the sample material, e.g., the first and second portions may be cut from a single biopsy sample or other piece of material. The first portion of the sample material may be contained in a first vessel, and a second portion of the sample material may be contained in a second vessel, where the first and second vessels are attached together. The first and second vessels may be arranged to suitably isolate the sample material from an exterior environment, e.g., to help prevent contamination and/or degradation of the sample material. The first portion of the sample material may be crushed while the first portion is contained in the first vessel, and the second portion may be stored in the second vessel for a histology analysis of the second portion of the sample material. In one embodiment, the first portion may be crushed while the first and second vessels are attached together, e.g., as part of a single, multiple vessel sample holder. Crushing may take place while the sample material is at a relatively low temperature, such as below −40 degrees C. A molecular analysis of first portion may be performed after crushing, e.g., to analyze whether the first portion includes one or more compounds. Depending on the outcome of the molecular analysis, a histology analysis of second portion may be performed. For example, if the molecular analysis of the first portion indicates the possible presence of a particular tissue morphology or other characteristic, the histology analysis may be performed to identify whether the morphology or other characteristic is present.
These and other aspects of the invention will be apparent from the following description and claims.
BRIEF DESCRIPTION OF THE DRAWINGS
Aspects of the invention are described with reference to illustrative embodiments shown in the drawings, in which like numerals reference like elements, and wherein:
FIG. 1 shows a perspective view of a sample holder having two vessels in an illustrative embodiment;
FIG. 2 shows a cross sectional view along the line2-2 ofFIG. 1;
FIG. 3 shows a cross sectional view of theFIG. 1 embodiment while a crushing force is applied to the sample material in the vessel;
FIG. 4 shows a cross sectional view of a vessel in another illustrative embodiment;
FIG. 5 shows a cross sectional view of a vessel in another illustrative embodiment in which the first and second layers are molded with a support structure and cap;
FIG. 6 shows a cross sectional view of a vessel in another illustrative embodiment including a cap that is threadedly engaged with a support structure;
FIG. 7 shows a cross sectional view of a vessel in another illustrative embodiment in which the first and second layers have a convex feature; and
FIG. 8 shows a cross sectional view of a vessel in another illustrative embodiment in which the first and second layers have a concave feature.
DETAILED DESCRIPTION
It should be understood that illustrative embodiments are described in accordance with aspects of the invention. However, the embodiments described are not necessarily intended to show or incorporate all aspects of the invention, but rather are used to describe a few illustrative embodiments. Thus, aspects discussed herein are not intended to be construed narrowly in view of the illustrative embodiments. In addition, it should be understood that aspects of the invention described may be used alone or in any suitable combination with other aspects also described.
FIG. 1 shows a perspective view of an illustrative embodiment of asample holder1 that incorporates one or more aspects of the invention. In this embodiment, thesample holder1 includes asupport structure2 that is made of a polymer material (such as polycarbonate, polyethylene, polypropylene, polyimide, PTFE, etc.) and has the overall size and shape of a conventional microscope slide. However, it should be understood that thesupport structure2 may have any size, shape or other configuration, and may be made of any suitable material, including glass, metal, composites, etc. Thesample holder1 includes two vessels3 including afirst vessel3aand asecond vessel3b,but may include only one vessel or three or more vessels. The vessels3 are configured differently in this embodiment, with thefirst vessel3abeing arranged to hold a sample material for crushing (discussed in more detail below), while thesecond vessel3bis arranged to hold a sample material for use in a histology analysis (e.g., thesecond vessel3bmay have the form of a standard histology cassette). However, the vessels3, if two or more are provided, may be arranged in the same or similar way, or may be arranged to hold samples for other purposes. For example, sample material may be stored for any suitable length of time and in a variety of different conditions based on the particular sample, its intended use, etc. Exemplary storage periods include short term storage for minutes (e.g., less than or equal to 30 minutes) or hours (e.g., less than or equal to 1 to 12 hours). Further exemplary storage periods include overnight storage or storage for 1 or more days, weeks, months, or years.
In accordance with an aspect of the invention, the vessels3 are separable from each other, e.g., by hand and without the use of tools. For example, in this embodiment, thesupport structure2 includes a line ofweakness21, such as a perforation, disengagable snaps or other fasteners, or other feature that allows the vessels3 to be separated from each other. Such a feature may be useful, for example, for harvesting the samples placed in the vessels at the same time and from the same subject while ensuring that the samples travel together for at least some portion of the analysis process. At some point in the process, the samples may be separated by separating the vessels3 from each other to permit the samples to be subjected to different analysis procedures. Anidentifier22, such as a barcode, RFID tag, alphanumeric text, a security feature (e.g., that interacts with an impacting machine to enable crushing of the sample and/or provides information to the machine for proper adjustment of a crushing force, impact energy, impact speed, or other crushing parameter) or other feature that allows thesample holder1 to be identified and/or be associated with the samples held in the vessels3, may be provided. Theidentifier22 may be used in a variety of different ways, e.g., to track the movement of thesample holder1, to associate information regarding a sample held by the vessels3 with thesample holder1 in a database, and so on. If thesample holder1 has separable vessels3 or other portions, the same ordifferent identifiers22 may be provided for the separable portions.
In this illustrative embodiment, thesupport structure2 defines asidewall23 of thevessel3a.Thevessel3ahas abottom opening24 and atop opening25 through which a sample material may be placed into thevessel3a.Although in this embodiment, thesidewall23 has a generally cylindrical or circular shape, thesidewall23 may have any suitable shape, such as conical, elliptical, square or other rectangular, triangular, or other shape. In addition, although thesidewall23 in this embodiment is defined by a hole in the planar body of the support structure as well as an upstanding portion on the planar body, thesidewall23 may be formed by any suitable structure(s). Thetop opening25 may be closed by a cap orother cover26 to ensure the sample material is kept in thevessel3a.Thecover26 may engage with thesupport structure2 to provide a fluid-tight and/or air-tight seal, e.g., to help isolate the sample material from an exterior environment. This feature may be useful to help ensure that the sample material does not degrade and/or is not contaminated after harvesting. In this embodiment, thecover26 includes alip27 that engages with thesidewall23 in a snap fit, interference fit, friction fit, or other suitable engagement. Thecover26 and/or thesupport structure2 may include one or more seal elements, such as a silicon O-ring seal, a lubricant, a threaded engagement or other arrangement to help form a suitable engagement of thecover26 with the support structure. Although in this embodiment thecover26 engages thesupport structure2 with a snap-fit, thecover26 may engage in other ways, such as by a screw thread, a clamp, clip or other fastener. Thecover26 may also include acover opening28, which may be generally aligned with thebottom opening24 when thecover26 is engaged with thesupport structure2.
In accordance with an aspect of the invention, both thebottom opening24 and thetop opening25 may be closed by a flexible film or layer that is arranged to transmit a crushing force to a sample material in thevessel3a.For example, a first layer of film may be attached to supportstructure2 to close thebottom opening24 and a second layer of film may be attached to thecover26 to close thecover opening28. Accordingly, when thecover26 is engaged with thesupport structure2 to close thevessel3a,the second layer of film and thecover26 may close thetop opening25 of thevessel3a.
FIG. 2 shows a cross sectional view of thevessel3aalong the line2-2 as shown inFIG. 1. Unlike that inFIG. 1, in this view, thecover26 is engaged with thesupport structure2 so as to close thetop opening25 of thevessel3a.In this embodiment, a first layer offilm4 is attached to thesupport structure2 so as to close thebottom opening24. Similarly, the second layer offilm5 is attached to thesupport structure2 by way of thecover26 to close thecover opening28.
That is, thesecond layer5 may be bonded to thecover26 and be attached to thesupport structure2 when cover is engaged with thesupport structure2. The first andsecond layers4 and5 may be attached in any suitable way, such as by adhesive, thermal bonding, mechanical clamps or other fasteners, and so on. Thus, the attachment of thelayers4,5 may be permanent (e.g., not intended for removal) or removable (e.g., by releasing a cover or a clamp, clip, or other fastener). With the first andsecond layers4,5 closing the bottom andtop openings24,25 of thevessel3a, thesample material10 is trapped in a space bounded by thesidewall23 and the first andsecond films4,5.
The first andsecond films4,5 and thesupport structure2 may be arranged to allow thesample material10 to be crushed while held in thevessel3a.For example, as shown inFIG. 3, thesample material10 may be impacted by a pair ofimpact elements11 that are sized and configured to apply a crushing force to thesample material10 by contacting the first andsecond films4,5. Thus, thesample material10 may be crushed without necessarily causing damage to the first andsecond films4,5 and/or thesupport structure2. As a result, thesample material10 may be crushed, e.g., in preparation for molecular analysis, while maintaining thesample material10 in a sealed environment. Deflection of the first andsecond films4,5 may vary depending on the application, and in some cases thefilms4,5 may deflect up to 1 mm or more where the sample material has a mass of about 50 milligrams or less. Of course, those of skill in the art will appreciate that thefilms4,5 may deflect to greater extents, such as up to 10 mm or more, and the sample material may have a larger mass, such as up to 250 milligrams or more.
In some embodiments, thefilms4,5 are flexible enough to deform nondestructively (e.g., without experiencing cracking, tearing, ripping or other degradation in structural integrity), or substantially nondestructively, in response to a mechanical impact sufficient to fragment thesample material10 contained within the sample vessel3. According to one feature, subsequent to the mechanical impact, thesample holder1 may maintain sufficient structural integrity to continue to separate thesample material1 from the external environment. For example, the vessel may maintain the sample in sterile isolation from the external environment. According to various implementations, the mechanical impact may have an impact energy transfer of about 1 to 25 Joules or more. In addition, the crushing force may be applied with thesample material10 and/or the vessel3 at cryogenic temperatures below about −20 degrees C. to about −80 degrees C. or less (such as about −196 degrees C.). Of course, in some embodiments, thesample holder1 may be arranged for use only at non-cryogenic temperatures, such as room temperature and/or temperatures above the freezing point of water.
Depending at least in part on the mechanical properties of the sample material10 (e.g., relatively hard, relatively soft, forms sharp or pointed shards when fragmented, etc.) and the temperature at which fragmentation is to occur, various materials may be used for thesample holder1. For example, a brain sample may require a particular film layer thickness (e.g., 1 mil layer of Kapton). Alternatively, a bone, seed, or rock sample, which may have sharp and or pointed features, may require a thicker film layer thickness (e.g., 4 mil layer of Kapton). Also, an additional reinforcement layer, for example, of a non-woven polymer material, such as Tyvek (™) (available from Dupont), reinforcement by woven or non-woven material, or other suitable reinforcement may be provided for thefilms4,5. In the example ofFIGS. 2 and 3, thefilms4,5 are formed as separate members (e.g., pieces of sheet material) that are attached to thesupport structure2, but in other configurations, thesample holder1 may be entirely, or include portions that are, injection molded as a single, unitary part. For example, theentire sample holder10 may be molded of a polyimide material, with various portions, including thesidewall23 andfilms4,5 molded as a single part, yet having a thickness and/or other structural arrangement to function as desired. In various embodiments, thesample holder1 may include, at least in part, a polyimide, polysulfone, liquid crystal polymer, fluorinated polymer, and/or other like material, e.g., as part of thefilms4,5.
In various embodiments, thesample holder10 may be sized and shaped for insertion into, and functional interoperation with, a mechanical impact device, such as that described in U.S. Patent Publication US 2005/0132775. For example, theimpact elements11 may include metal members that are driven together by a hammer, an electromagnetically-driven solenoid piston, a pneumatically-actuated device, a hydraulically-actuated device, a gravity actuated device, or any other suitable mechanism. Also, one of theimpact elements11 may remain stationary while only oneelement11 moves toward the other rather than having bothelements11 move. Although the impact device may operate a cryogenic temperatures, the impact providing device may also operate at or about room temperature while still applying a crushing force when thesample material10 is at cryogenic temperatures. That is, even though the impact device may be at room temperature, the impact device may operate quickly enough so that the transient exposure of thesample holder1 to theimpact elements11 does not substantially warm thesample material10. This is also the case where thesample material10, itself, is maintained at room or near room temperature. In various embodiments, the impact device may provide elements for heating or cooling the sample prior or subsequent to fragmenting it. For example, one or both of theimpact elements11 may be chilled (e.g., by liquid nitrogen), and contact of thesample holder1 with one or both of theimpact elements11 may chill thesample material10. The mechanical impact from theimpact elements11 may provide a force sufficient to disrupt the macro-structure of thesample material10, and fragment it into a plurality of pieces in the vessel3. Illustratively, the impact force may be between about 1 Joule and about 25 Joules. Theimpact elements11 may impact the vessel3 one or more times to achieve the desired sample fragmentation. For example, the vessel3 andsample material10 may be contacted 1 to 5, or more times, and each impact may have the same or different force or impact energy applied. For example, the impact force may be initially larger to break a large sample into fragments, and then be reduced.
In some embodiments, thesample holder1 may also be arranged for use with other types of sample preparation devices than an impact device. For example, thesample holder1 may be arranged for use with an acoustic treatment device, such as that described in U.S. Pat. No. 6,948,843. Thus, thesample holder1 may be used to provide focused acoustic energy to the sample contained within the vessel for performing any one of: cooling; heating; fluidizing; mixing; stirring, disrupting, increasing permeability of a component of, enhancing a reaction of, sterilizing; and/or further fragmenting the sample material.
FIGS. 1-3 show only one illustrative embodiment, and a sample holder that incorporates one or more aspects of the invention may be arranged in other ways. For example,FIG. 4 shows a cross sectional view of an embodiment that is arranged like that inFIG. 1, with a difference being that thefirst film4 is attached to thesupport structure2 above the bottom surface of thesupport structure2 to close thebottom opening24. In addition, thesecond film5 is attached to thecover26 below the cover's upper surface to close thecover opening28. As with other embodiments, the first andsecond films4,5 may be molded integrally with thesupport structure2 and/or acover26, or arranged in other suitable ways.FIG. 5 shows another illustrative embodiment in which the first andsecond films4,5 are attached to thesupport structure2 and thecover26 at a location that is intermediate that shown inFIGS. 2 and 4. With the arrangement shown inFIG. 5, thefilms4,5 may be clamped by portions of the supportingstructure2 or thecover26, or thesupport structure2 and/or cover26 may be molded to surround the edges of thefilms4,5 (e.g., pieces of suitable sheet material for thefilms4,5 may be provided into an injection mold, and the supportingstructure2 and cover26 co-molded to envelop the edges of the sheet material).
As discussed above, thefilms4,5 may be clamped in place so as to attach thefilms4,5 to thesupport structure2 and/or the cover26 (if provided). For example,FIG. 6 shows an illustrative embodiment in which thefirst film4 is attached to a bottom surface of asupport structure2 to close abottom opening24 defined by asidewall23, and asecond film5 is attached to a top surface of thesupport structure2 to close atop opening25 defined by the sidewall23 (e.g., where thesidewall23 is defined by a hole in the support structure2). While in this embodiment thefirst film4 is permanently bonded to thesupport structure2, e.g., by thermal welding, adhesive, etc., thesecond film4 may be clamped in place and be removable from thesupport structure2. While the clamping arrangement may be configured in a variety of different ways, in this embodiment the clamp includes a ring31 (which may also be referred to as a cover26) that has a threaded portion that engages with a threaded portion of the supportingstructure2. By threadedly engaging thering31 to thesupport structure2, thering31 may squeeze thesecond film5 between thering31 and thesupport structure2, attaching thesecond film5 to thesupport structure2. Of course, thesecond film5 may be bonded to the lower surface of thering31, if desired, rather than be separate from thering31.
In another aspect of the invention, the first and/orsecond films4,5 may be arranged to help position thesample material10 as desired in the vessel3. For example,FIG. 7 shows an arrangement that is like that inFIG. 2, except that the first andsecond films4,5 each have aconvex portion4a,5athat extends into thevessel3a.Theconvex portions4a,5aare present in thefilms4,5 without an external force being applied to thefilms4,5 (e.g., are molded into thefilms4,5) and may be arranged so as to clamp or otherwise squeeze thesample material10 between thefilms4,5, thereby helping to hold thesample material10 in place. Thus, once thecover26 is engaged with the support structure2 (or the vessel3 is otherwise closed), thesample material10 may be held as desired in the vessel, e.g., for later impact processing. Theconvex portions4a,5amay be molded or otherwise formed into thefilms4,5, and may be compliant to a desired extent. In one embodiment, theconvex portions4a,5amay have a dome-like shape with a largest diameter of about 5 mm and a height of about 2 mm. In this embodiment, thebottom opening24 and coveropening28 may have a diameter of about 20 mm. Of course, it should be understood that other dimensions and shapes other than circularly-shaped openings and convex portions are possible. For example, the openings and convex portions may have an elliptical shape, square shape, and others. It should also be understood that only one of thefilms4,5 may have a convex portion, while the other film may be substantially flat or have other arrangements.
For example,FIG. 8 shows an embodiment in which the first andsecond films4,5 each have aconcave portion4b,5bthat extends away from the vessel3. Another difference in this embodiment as compared to that inFIG. 2 is that thesecond film5 is attached to a bottom surface of thelip27 of thecover26. As discussed above, thecover26 may engage thesupport structure2 in any suitable way, such as by interference fit, threaded engagement, clamp, etc. In this embodiment, engagement of thecover26 with thesupport structure2 may also serve to clamp thesecond film5 to a surface of thesupport structure2, although this arrangement is not necessary.
Aconcave feature4b,5bprovided with thefilms4,5 may also help position asample material10 as desired in a vessel3. For example, a concave feature4bon thefirst film4 may provide a depression or well into which thesample material10 may be placed. Thus, thesample material10 may naturally move to a center of the vessel3, e.g., by the force of gravity. Although in this embodiment, thesecond film5 also has a concave feature, thesecond film5 could include a convex feature like that inFIG. 8 which may be used to provide a biasing force on thesample material10 to keep thesample material10 in the center of the concave portion4bof thefirst film4.
After suitable treatment of thesample material10 in the vessel3, such as freezing, crushing, acoustic treatment to further break the material into smaller particles, etc., the vessel3 may be opened and thesample material10 transferred to anothersample holder1. In one embodiment, thesample holder1 may be arranged to sealingly couple with another sample holder, such as a tube, to help ease transfer of thesample material10. For example, thevessel3ainFIG. 1 may opened by lifting thecover26 and a tube engaged with thesidewall23 of thesupport structure2. Then, thesupport structure2 andvessel3amay be inverted, causing thesample material10 to be transferred into the tube.
Embodiments in accordance with the invention may be arranged to accommodate an increase in air or other gas pressure in the vessel3 during crushing of thesample material10. That is, when thesample material10 is impacted in some embodiments, the volume of the vessel3 may be decreased, if only momentarily, increasing the gas pressure in the vessel3. To compensate, and while maintaining a sealed environment for the sample material, the vessel3 may be arranged to “burp”, i.e., to release gas through a one-way valve, through a seal between thecover26 andsupport structure2 or other pathway when the sample is impacted. While gas may be released from the vessel3, thesample holder1 may be arranged to prevent the inflow of gas into the vessel3, thus maintaining the sample material isolated from an external environment. In other embodiments, thefilms4,5 and/or other portions of thesample holder1 may be arranged to accommodate an increase in gas pressure. For example, portions of thefilms4,5 that are not contacted by theimpact elements11 or other similar structures during crushing may move to accommodate gas in the vessel3 so as to maintain the same pressure or another elevated pressure that does not compromise a seal of the vessel3. In one embodiment, one or bothfilms4,5 may include a convex portion in areas not contacted by theimpact elements11 that move (e.g., from a convex configuration to a concave configuration) to accommodate an increase in gas pressure. Other arrangements are possible, such as a gas reservoir, a pressure release valve, etc.
Other aspects of the invention relate to methods for processing sample material. In one aspect, a method for treating a sample material includes providing a sample material between top and bottom flexible films where the flexible films are connected together by a substantially rigid support structure that surrounds the sample material, and applying a crushing force to the sample material via the top and bottom flexible films. As discussed above, by having the films connected together by a substantially rigid structure that is interposed between the films and surrounds the sample material, the sample material may be contained in a relatively defined area that is easily accessed. The flexible films may include suitable features, such as a concave or convex shape that contacts the sample material. Such features may be useful to help locate the sample material for crushing and/or removal. The crushing force may be applied while the sample material is at a temperature less than about −40 degrees C. and without cracking, tearing, or ripping the top and bottom flexible films.
In another aspect of the invention, a method for treating a sample material includes providing first and second portions of a sample material, where a first portion of the sample material is contained in a first vessel, and a second portion of the sample material is contained in a second vessel. The first and second vessels may be attached together, e.g., by a line of weakness or other feature that allows the vessels to be separated from each other by hand and without tools. The first portion of the sample material may be crushed while the first portion is contained in the first vessel, and the second portion may be stored in the second vessel for a histology analysis of the second portion of the sample material.
In some embodiments, crushing of the first sample may be performed while the first and second vessels are attached together, e.g., while the first sample is at cryogenic temperatures. Crushing of the sample may prepare it for a molecular analysis, such as testing to discover the presence of one or more compounds in the sample. Depending on the outcome of the molecular analysis, a histology analysis of the second portion may be performed.
Having thus described several aspects of at least one embodiment of this invention, it is to be appreciated various alterations, modifications, and improvements will readily occur to those skilled in the art. Such alterations, modifications, and improvements are intended to be part of this disclosure, and are intended to be within the spirit and scope of the invention. Accordingly, the foregoing description and drawings are by way of example only. It will be apparent that other embodiments and various modifications may be made to the present invention without departing from the scope thereof. The foregoing description of the invention is intended merely to be illustrative and not restrictive thereof. The scope of the present invention is defined by the appended claims and equivalents thereto.

Claims (32)

The invention claimed is:
1. A sample holder comprising:
a support structure defining a substantially rigid sidewall of a vessel, the support structure defining a bottom opening and a top opening,
a first layer of flexible film attached to the support structure, the first layer of film covering the bottom opening;
a second layer of flexible film attached to the support structure, the second layer covering the top opening; and
a cap removably engagable with the support structure so as the close the top opening of the vessel, wherein the cap is arranged to sealing engage the second layer with the support structure to cover the top opening,
wherein the first and second layers of film are separated from each other by the sidewall and are arranged to transmit a crushing force exerted on the first and second layers to crush a sample material contained in the vessel.
2. The holder ofclaim 1, wherein at least a portion of the sidewall extends from a generally planar body of the support structure.
3. The holder ofclaim 2, wherein the sidewall has a cylindrical shape and extends upwardly from the generally planar body.
4. The holder ofclaim 1, wherein the support structure defines sidewalls for two separate vessels.
5. The holder ofclaim 1, wherein the first and/or second layer have a convex shape such that a portion of the first and/or second layer extends into the vessel.
6. The holder ofclaim 1, wherein the first and/or second layer have a concave shape such that a portion of the first and/or second layer extends away from the vessel.
7. The holder ofclaim 1, wherein the first and/or second layer is formed of a polyimide, a polysulfone, a fluorinated polymer or a liquid crystal polymer.
8. The holder ofclaim 1, wherein the first and second layers are arranged to transmit the crushing force to the sample material while at temperatures less than about −40 degrees C.
9. The holder ofclaim 1, wherein the first and second layers are arranged to transmit the crushing force to the sample material at temperatures less than about −40 degrees C. without cracking, tearing, or ripping when exposed to the crushing force.
10. The holder ofclaim 1, wherein the first and second layers are arranged to transmit the crushing force to the sample material where the crushing force transfers energy to the sample material of at least about 10 Joules.
11. The holder ofclaim 1, wherein the first and second layers have a thickness of between about 0.0005 and 0.0005 inches.
12. The holder ofclaim 1, wherein the vessel is sealed in a substantially air tight fashion with the first and second layers covering the bottom and top openings, respectively.
13. The holder ofclaim 1, wherein the top and bottom openings have a size of about 20 mm.
14. The holder ofclaim 1, wherein the first layer includes a convex portion that extends into the vessel and has a dome shape with an outer diameter of about 5 mm and a height of about 2 mm.
15. The holder ofclaim 1, wherein the support structure is arranged for use as a standard microscope slide.
16. The holder ofclaim 1, wherein the sidewall has a height of about 2 mm to about 10 mm.
17. The holder ofclaim 1, wherein the support structure defines a second vessel arranged to hold a sample suitable for microtome processing.
18. A sample holder comprising:
a support structure defining first and second vessels, each of the vessels including a top opening,
first and second covers that are each removably engagable with the support structure so as to close the top opening of the first and second vessels, respectively; and
wherein the first vessel is arranged to contain a first sample material and transmit a crushing force exerted on the first vessel to the first sample material to crush the first sample material,
wherein the first vessel includes a bottom opening opposite the top opening, the sample holder further comprising:
a first layer of flexible film attached to the support structure, the first layer of film cover the bottom opening of the first vessel; and
a second layer of flexible attached to the support structure, the second layer covering the top opening of the first vessel,
wherein the first and second layers of film are separated from each other by a portion of the support structure and are arranged to transmit a crushing force exerted on the first and second layers to crush a sample material contained in the vessel, and
wherein the second vessel is arranged to contain a second sample material suitable for a histology analysis.
19. The sample holder ofclaim 18, wherein the first and second vessels are separable from each other without the use of tools.
20. The sample holder ofclaim 18, wherein the first cover includes a cover opening, and the second layer of flexible film is attached to the cover to close the cover opening, and wherein the second layer of flexible film covers the top opening of the first vessel with the first cover engaged with the support structure.
21. The sample holder ofclaim 18, wherein the first and second layers are arranged to transmit the crushing force to the sample material at temperatures less than about −40 degrees C. without cracking, tearing, or ripping when exposed to the crushing force.
22. The sample holder ofclaim 18, wherein the first and second layers are arranged to transmit the crushing force to the sample material where the crushing force transfers energy to the sample material of at least about 10 Joules.
23. The sample holder ofclaim 18, wherein the first and second layers have a thickness of between about 0.0005 and 0.0005 inches.
24. The sample holder ofclaim 18, wherein the first vessel is sealed in a substantially air tight fashion with the first and second layers covering the bottom and top openings, respectively.
25. A sample holder comprising:
a support structure defining a substantially rigid sidewall of a vessel, the support structure defining a bottom opening and a top opening,
a first layer of flexible film attached to the support structure, the first layer of film covering the bottom opening,
a second layer of flexible film attached to the support structure, the second layer covering the top opening,
wherein the first and second layers of film are separated from each other by the sidewall and are arranged to transmit a crushing force exerted on the first and second layers to crush a sample material contained in the vessel, and
wherein the support structure is arranged for use as a standard microscope slide.
26. The holder ofclaim 25, wherein at least a portion of the sidewall extends from a generally planar body of the support structure.
27. The holder ofclaim 25, wherein the first and/or second layer is formed of a polymide, a polysulfone, a fluorinated polymer or a liquid crystal polymer.
28. The holder ofclaim 25, wherein the first and second layers are arranged to transmit the crushing force to the sample material while at temperatures less than about −40 degrees C.
29. The holder ofclaim 25, wherein the first and second layers are arranged to transmit the crushing force to the sample material at temperatures less than about −40 degrees C. without cracking, tearing, or ripping when exposed to the crushing force.
30. The holder ofclaim 25, wherein the first and second layers are arranged to transmit the crushing force to the sample material where the crushing force transfers energy to the sample material of at least about 10 Joules.
31. The holder ofclaim 25, wherein the first and second layers have a thickness of between about 0.0005 and 0.005 inches.
32. The holder ofclaim 25, wherein the vessel is sealed in a substantially air tight fashion with the first and second layers covering the bottom and top openings, respectively.
US12/984,9192011-01-052011-01-05Sample holder and method for treating sample materialActive2032-04-01US8709359B2 (en)

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